The force of a falling snowflake is determined by its mass and acceleration due to gravity. As the snowflake falls, it experiences air resistance which counteracts the force of gravity to some extent. The force of a falling snowflake is usually very small due to its light weight.
The average speed of a falling snowflake is around 1 to 6 kilometers per hour, depending on various factors such as the size and shape of the snowflake, temperature, and air currents. Snowflakes can fall faster during heavy snowfall or when influenced by strong winds.
The force that stops a box from falling through a table is the normal force. This force is exerted by the table in the upward direction and counteracts the downward force (weight) of the box, preventing it from falling through the table.
A falling elephant encounters a greater force of air resistance than a falling feather does. The force of air resistance can't be greater than the weight of the falling object. When the force of air resistance is equal to the weight of the falling object, the object stops accelerating, its falling speed becomes constant, and the force of air resistance doesn't get any bigger. So the force of air resistance against a falling feather can't be greater than the weight of the feather. But the force of air resistance against a falling elephant can be, and undoubtedly is, greater than the weight of a feather.
A box is sitting on a table. The upward force exerted on the box that stops it from falling through the table is known as the force.
When falling, the force that pulls you up is called the normal force. This force is exerted by a surface (such as the ground) in reaction to the force of gravity pulling you downward. The normal force acts perpendicular to the surface and prevents objects from passing through it.
snowflake
The average speed of a falling snowflake is around 1 to 6 kilometers per hour, depending on various factors such as the size and shape of the snowflake, temperature, and air currents. Snowflakes can fall faster during heavy snowfall or when influenced by strong winds.
yes they do they stick to others as they are falling but they dont grow after falling
You would need a great quality camera with high resolution. Also, a macro lens for your camera would be great in capturing a picture of a falling snowflake.
The average snowflake falls at a speed of about 3.1 miles per hour (5 kilometers per hour) due to air resistance. However, the speed can vary depending on the size and shape of the snowflake.
it was about 50000 cm i dont know myself soz
Falling with Force - 2009 was released on: USA: March 2009
The force that stops a box from falling through a table is the normal force. This force is exerted by the table in the upward direction and counteracts the downward force (weight) of the box, preventing it from falling through the table.
Graupel, also called soft hail or snow pellets, refers to precipitation that forms when supercooled droplets of water are collected and freeze on a falling snowflake.
Gravitational force
A falling elephant encounters a greater force of air resistance than a falling feather does. The force of air resistance can't be greater than the weight of the falling object. When the force of air resistance is equal to the weight of the falling object, the object stops accelerating, its falling speed becomes constant, and the force of air resistance doesn't get any bigger. So the force of air resistance against a falling feather can't be greater than the weight of the feather. But the force of air resistance against a falling elephant can be, and undoubtedly is, greater than the weight of a feather.
That all depends on the strength and direction of the force. If the object is already "falling", then there must already be the force of gravity acting on it. The effect of any other force will depend on how the strength and direction of the other force relates to the strength and direction of the gravitational force. -- If the new force is directed up, it will slow the falling object, and possibly even make it stop falling and start rising. -- If the new force is directed down, it will make the falling object fall faster. -- If the new force is horizontal, it will make the object move horizontally as well as continuing to fall. -- If the new force is horizontal and strong enough, it will place the falling object into Earth orbit.